EA023061B1 - Fast freezer, preferably for polymeric packets filled with biological medicinal substances - Google Patents

Abstract

The invention relates to the field of refrigeration or freezing technology and is intended for fast-freezing polymeric packets filled with biological substances. The fast freezer comprises a refrigeration unit, a pump for coolant pumping, heat exchangers, a cooling device comprising thermoelectric modules, one surface of which is in contact with heat exchangers and the other surface is in contact with heat-conducting plates that contact the packets to be cooled. The first embodiment of the fast freezer comprises, for each packet, a device for agitating its contents, and the power supply source of the thermoelectric modules is connected to a device for controlling the operating modes of the power supply source, said device being connected to a device for determining the temperature difference between the hot and cold junctions, the latter device being connected to an independent power supply unit. The second embodiment of the fast freezer comprises a thermal shutoff adjoining the heat insulating wall and being in the form of a radiator, wherein all of the cables are passed in grooves in said radiator, heat exchangers are mounted on one side of said radiator, and the second side is in contact with the cold junction of the thermoelectric modules, the thermal shutoff being connected to an independent power supply unit. The devices according to the invention provide higher freezing rate. The cooling device comprises thermoelectric modules connected to a power supply source and mounted, with gaps, in a technological cavity formed by a cooled surface and hot-junction heat exchangers, the free volume of the technological cavity being filled with liquid thermal insulation with a layer thickness that is less than the height of the thermoelectric modules, which provides an increase in the operating efficiency of the device due to a higher refrigeration factor.

Description

The invention relates to the field of refrigeration or freezing technology and is intended for the rapid freezing of various solutions, in particular blood plasma, placed in polymer bags.

State of the art

Two-stage compressor quick freezers RLZMLRKOZT are known, in which packages with plasma are cooled by direct contact with the surface of the shelves, inside which refrigerant circulates through the coils, and the second side of the packages comes in contact with a pressure plate made of aluminum. The disadvantages of the known device are the active cooling of only one side of the plasma packets in contact with the shelf to be cooled, the use of a complex two-stage refrigeration machine using different refrigerants K404A and K23 for each of the cooling stages.

GEMOTERM-быст quick-freezers are also known, in which a high speed of freezing packages with plasma is achieved by using a mechanical trolley with packages, moving with acceleration, periodically changing in size and direction, which ensures mixing of the contents of the packages, eliminating the formation of ice crust, which is difficult due to low thermal conductivity freezing plasma. HEMOTERM-quick-freezers provide freezing of containers with plasma either in a stream of forcibly circulating air cooled to a temperature of minus (40-50) ° C, or in an environment of a liquid coolant (ethyl alcohol) pre-cooled to a temperature of minus (40-50) ° C. Freezing in low-temperature air leads to the use of complex two-stage chillers, and the low heat capacity of the air eliminates the effective removal of heat from plasma containers. The process of freezing in a cooled liquid coolant shortens the freezing time, but increases the fire and explosion hazard of the room, into which the alcohol vaporized from the containers after they are removed, there is a real risk of thermal damage to the personnel when it comes in contact with cold alcohol, above the surface of the cold alcohol when installing and removing containers fog is formed with plasma, which impedes the work of personnel, and the entrainment of alcohol with packets and the ingress of moisture into the air tank leads to a decrease in alcohol concentration and the need to periodically compensate for its loss.

The closest in technical essence and the achieved result is a quick-freezer known from KI patent 2310143 C1 02.15.2006, containing a refrigerating machine with a closed hydraulic line filled with a cooled liquid and connected to the pump through heat exchangers connected in parallel to this line, in contact with one surface of thermoelectric modules , and the second surface is in contact with heat-conducting plates, between which there is a cooled package in contact with them, while t thermoelectric modules are equipped with their own power supply, and temperature sensors are installed on the heat-conducting plates connected to a control and monitoring system that is connected to a current polarity switch connected to the thermoelectric modules power supply, while the power supply, control and monitoring system are isolated from heat-conducting plates with the cooled packages placed between them by a heat-insulating wall through which the control and power cables of thermoelectric modules pass.

Due to the lack of adjustment of the power source, the thermoelectric module operates in a constant mode regardless of the stage of freezing.

The disadvantage of a quick-freezer is the influx of a large amount of heat to cooling heat-conducting plates, on which thermoelectric modules and temperature sensors are installed, which are connected by copper wires to a power source of thermoelectric modules and a control and monitoring system located outside the cooling zone. The large thermal conductivity of copper and the large cross-section of wires, determined by the significant currents consumed by thermoelectric modules, leads to an increase in the thermal load on them by several tens of watts, which increases the time of freezing packages with plasma.

SUMMARY OF THE INVENTION

The technical result of the invention is to reduce the freezing time of products and solutions, in particular blood plasma, placed in polymer bags.

The specified technical result is achieved due to the fact that in the quick-freezer, polymer bags, mainly filled with biological medical substances, according to the second embodiment, contain a refrigeration unit with a closed hydraulic line, filled with a cooled liquid and connected to the pump through heat exchangers connected in parallel to this line, in contact with one surface of thermoelectric modules, the second surface of which is in contact with heat-conducting plates, contact in turn, with a cooled bag placed between them, while the thermoelectric modules are equipped with their own power supply, and temperature sensors are installed on the heat-conducting plates connected to a control and monitoring system that is connected to a current polarity switch connected to the power supply unit of thermoelectric modules, while the power supply unit, the control and monitoring system are isolated from heat-conducting plates with cooled packages placed between them by a heat-insulating wall, through the power cables of thermoelectric modules and control pass, unlike the known one, a thermal shutter is introduced, adjacent to the heat-insulating wall and made in the form of a radiator made of material with high thermal conductivity, in the grooves of which pass all the cables, on one side of which heat exchangers are installed, and the second the side is in contact with the cold junction of thermoelectric modules, while the thermal shutter is connected to an autonomous power source.

The task of quick freezing is solved by the fact that all the power cables of thermoelectric modules, control and monitoring systems are cooled in a thermal shutter, reducing the thermal load on thermoelectric modules that freeze polymer bags.

The invention is illustrated by the drawing, which schematically presents a quick-freezer, providing cooling of one package.

Examples of a preferred embodiment of the invention

Cooling of any required number of packages is carried out by docking the proposed device to a closed hydraulic line in any way, by any connectors of an additional number of hydraulic paths of heat exchangers providing cooling of hot junctions of thermoelectric modules, between which the required number of polymer bags are cooled through heat-conducting plates. This allows you to place either all polymer bags for quick freezing in a separate freezer case, or in parts in separate thermostats through which a cooled coolant is pumped through the tracts, combined by a closed hydraulic line with a small number of polymer bags, for example, five to six pieces.

The proposed quick-freezer comprises a refrigerating machine 1 with a closed hydraulic line 2 filled with coolant, which is pumped by a pump 3 through heat exchangers 4, which are in contact with one of the sides of the thermoelectric modules 5. The other side of the thermoelectric modules 5 is in contact with heat-conducting plates 6, between which the contact with they cooled polymer bag 7, filled, for example, with blood plasma. Thermoelectric modules 5 are equipped with their own power supply unit 8, and temperature sensors 9 are installed on the heat-conducting plates 6, which are connected to a control and monitoring system 10 connected to a current polarity switch 11 connected to a power supply unit 8 of thermoelectric modules 5. Power supply unit 8, control system and control 10 are isolated from heat-conducting plates 6 with placed between them cooled packages 7 heat-insulating wall 12, which is adjacent to the thermal shutter 17, powered from an autonomous source 18, through the cat The power cables of thermoelectric modules 5 and control pass in the form of a radiator made of a material with high thermal conductivity, for example, aluminum of the AMC brand, in the grooves of which pass all the cables, on one side of which heat exchangers are installed, through which heat is transferred to the refrigerator, and the second side in contact with the cold junction of thermoelectric modules 5, while the thermal shutter 17 is connected to an autonomous power source 18.

The device operates as follows.

Start the refrigeration unit 1. Turn on the pump 3, which circulates the coolant in a closed hydraulic circuit 2, cooled in the refrigeration unit 1 to the required subzero temperature, for example to -5 ° C. The power supply unit of the thermoelectric modules 8 is connected to the power supply network, due to which the electric power through the current polarity switch 11 enters the thermoelectric modules 5, the temperature measuring and control device 10, the autonomous power supply of the thermoelectric thermal shutter modules 17. The surfaces of the thermoelectric modules 5 in contact with heat exchangers 4, start to release heat, which is discharged through heat exchangers 4 into the coolant of the closed hydraulic line 2 and enters the refrigeration unit 1. Surfaces atom thermoelectric modules 5 in contact with the heat-conducting plates 6, start cooling upper and lower surface of resin package 7, 7, resulting in the accelerated cooling. The cooled heat carrier passes through the heat exchangers 4 and removes heat from the hot surfaces of the thermoelectric modules 5, keeping the temperature of these surfaces stable and lower than the ambient temperature. With the passage of current from the power supply unit 8 through thermoelectric modules 5 with cooled heat-generating surfaces, the temperature of their opposite surface decreases to the required value set in advance for each stage. Since the cooling of the bag 7 occurs uniformly over two surfaces, freezing to a predetermined temperature occurs in a time not exceeding 30 minutes. According to temperature sensors 9, the temperature measuring and control device 10 gives a signal about the end of the freezing process, by which the thermoelectric modules 5 are disconnected from the power supply 8. The cooling rate of the polymer bag 7 depends on the heat-insulating walls 12 of the freezer or thermostat and the amount of heat supplied through the cables. When passing through the thermal shutter 17, the cables are cooled, reducing the heat load on the thermoelectric modules 5, reducing the time to reach the set temperature in the polymer bag 7.

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To implement the proposed technical solution, thermoelectric modules PM-127-14-11-11-72-B of the company Crystal LLC can be used as thermoelectric modules 5 and cooling devices in a thermal shutter 17, as 6 temperature sensors 9 installed on heat-conducting plates 9 - measurement sensors temperatures Ό818Β20, which are connected to the control and monitoring system 10, for example, to the P1C 12C508A or P1C 12CE674 controller from Myugosyr company or to the AT918AM78 microcontroller from A! she1.

Calculations show that the compensation in the thermal shutter of heat influx through the cables for the quick-freezer by six packets with plasma allows to reduce the time of freezing the contents of the package with a capacity of 0.3 l for 120 s with constant thermoelectric modules and preserving the freezing algorithm.

Industrial applicability

The proposed quick-freezer of predominantly polymer bags filled with biological medical substances, such as blood plasma, surpasses all similar devices in terms of freezing speed, is notable for its ease of use and great reliability.

Claims (1)

CLAIM The quick-freezer is predominantly filled with biological medical substances plastic bags containing refrigeration unit (1) with a closed hydraulic line (2), filled with cooled liquid and connected to the pump (3) through heat exchangers (4) connected in parallel with this line (2) surface of thermoelectric modules (5), the second surface of which is in contact with heat-conducting plates (6), which are in contact, in turn, with a cooled bag placed between them m (7), while thermoelectric modules (5) are equipped with their own power supply unit (8), and heat-conducting plates (6) have temperature sensors (9) connected to the control and monitoring system (10) that is connected to the switchboard (11 ) polarity of current connected to power supply unit (8) of thermoelectric modules (5), while power supply unit (8), control and monitoring system (10) are insulated from heat-conducting plates (6) with heat-insulated wall placed between them (7) (12) through which thermoelectric power cables pass modules (5) and controls, characterized in that it additionally contains a thermal shutter (17) adjacent to the heat insulating wall (12) and made in the form of a radiator from a material with high thermal conductivity, in the grooves of which all cables run, on one side of which heat exchangers are installed, and the second side is in contact with the cold junction of thermoelectric modules (5), while the thermal shutter is connected to an independent power supply (18).